tbengy Python Tool for SV/UVM Testbench Generation and RTL Synthesis. The tool uses newly available capability of Vivado tool by Xilinx (WebPack Version) to compile and run SV/UVM Testbench and syntheize RTL for Digilent FPGA Boards
- Python 3.x
- Xilinx Vivado 202x.x
- GNU Make
- Download Python3 from https://www.python.org/downloads/
- Install Python3 in your system
- Check Python version in Terminal/Console/Command-Prompt/Powershell
python --version
Or
python3 --version
Python 3.8.1
- Download Vivado from https://www.xilinx.com/support/download.html
- Install Vivado WebPack in your system
- Set Xilinx Vivado bin folder path to User/System Environment Variables
export PATH="$PATH:/home/<path_to_xilinx_installation>/Xilinx/Vivado/2020.1/bin"
Note: Put the above line with your path in ~/.bashrc, so the tool can load everytime you open terminal
- Once you set the path in ~/.bashrc, open new terminal and execute command below
vivado
- If your path and setup is correct, Vivado GUI will open
- You can close it as we will be working from terminal for the tbengy
Open Command-Prompt as administrator
setx path "%path%;<path_to>Xilinx\Vivado\2020.1\bin"
Example: setx path "%path%;C:\Xilinx\Vivado\2020.1\bin"
You can also set the path from System Properties. Search online for this method.
- Once you set the path in Windows, open new command-prompt/Powershell and execute command below
vivado
- If your path and setup is correct, Vivado GUI will open
- You can close it as we will be working from command-prompt/Powershell for the tbengy
- Most Linux come with GNU Make so no need to do this step if you are running using Linux
- For Windows, download GNU Make and install it from http://gnuwin32.sourceforge.net/packages/make.htm
- After installation in Windows, we need to add the bin path of Make in system path variable as we did for Vivado
setx path "%path%;<path_to>Program Files (x86)\GnuWin32\bin\"
Example: setx path "%path%;C:\Program Files (x86)\GnuWin32\bin"
- After adding the path, open new command-prompt/Powershell window and run
make
- If you see make getting executed, you are good to go
- Run the command below if you are using Git to clone the repository anywhere you wish
git clone https://github.com/prasadp4009/tbengy.git
Or
-
Download from link - https://github.com/prasadp4009/tbengy/archive/master.zip
-
Unzip the master.zip if downloaded and then go to tbengy directory
-
Open new Terminal/Console/Command-Prompt/Powershell in that directory
-
Run the command below to generate UVM TB
python tbengy.py
Or
python3 tbengy.py
tbengy help can be accessed with:
python tbengy.py -h
Or
python3 tbengy.py -h
You should get the following output
usage: tbengy.py [-h] [-v] (-l | -m <module_name>) [-t <tb_type>] [-b <board_type>] [-f <fpga>] [-d <dir_path>]
optional arguments:
-h, --help show this help message and exit
-v, --version Show tbengy version and exit
-l, --listboards Show the list of available boards and exit
-m <module_name>, --modulename <module_name>
Module name for which TB to be generated. Ex. -m my_design
-t <tb_type>, --tbtype <tb_type>
Testbench type to be generated. Ex. -t uvm or -t sv
-b <board_type>, --boardtype <board_type>
Board Files to be added. Ex. -b zybo, -b nexys4_ddr, -b zybo-z7 etc.
-f <fpga>, --fpga <fpga>
FPGA used in board. Ex. -f xc7z010clg400-1, -f xc7a100tcsg324-1, -f xc7z010clg400-1 etc. for Zybo, Nexys 4 DDR and Zybo-Z7-10 respectively
-d <dir_path>, --dirpath <dir_path>
Directory under which TB should be generated. Ex. -d ./myProjects/TB. Default is present working dir.
- Enter you module name with '-m <module_name>', the tool will generate a complete UVM testbench (default tb_type is UVM)
python tbengy.py -m my_design
Or
python3 tbengy.py -m my_design
- You can enter desired directory where you want to generate TB by passing '-d <directory_path>'
python tbengy.py -m my_design -d ./myProjects/
Or
python3 tbengy.py -m my_design -d ./myProjects/
- Go to your generated module folder
- You can read the generated README.md to understand directory structure
- To run the testbench, go to scripts directory and run command below
- For generating SV TB you need to add an additional flag '-t sv' along with primary generation command as shown below
python tbengy.py -m my_design -d ./myProjects/ -t sv
Or
python3 tbengy.py -m my_design -d ./myProjects/ -t sv
- For generating SV TB with Synthesis on Digilent Boards, you need to add flag '-t sv -b <board_name> -f ' along with primary generation command as shown below
- You should be able to find FPGA part name from Board Reference Manual or Vendor website
- The default RTL contains Blink LED program, which is basically a simple clock divider with output of 1Hz to LED
- The command also pics up correct board files and link them in script. Modified board files are already available in ./digilent-xdc directory
- These files are modified with additional information regarding clock frequencies and mapped to ports in design RTL by default
- To check the list of boards run the below command
python tbengy.py -l
Or
python3 tbengy.py -l
- Example for Zybo Board
python tbengy.py -m zyboBlink -d ..\myProj\ -b zybo -f xc7z010clg400-1 -t sv
Or
python3 tbengy.py -m zyboBlink -d ..\myProj\ -b zybo -f xc7z010clg400-1 -t sv
- Example for Nexys 4 DDR
python tbengy.py -m nddr4Blink -d ..\myProj\ -b nexys4-ddr -f xc7a100tcsg324-1 -t sv
Or
python3 tbengy.py -m nddr4Blink -d ..\myProj\ -b nexys4-ddr -f xc7a100tcsg324-1 -t sv
make run_all
make run_all_gui
make synth
Note: You can have multiple boards connected to system. Do make sure the boards are connected and turned on.
Contact me on [email protected] for any questions.
Hope the tool helps. Thanks!
- Generation of UVM Testbench with RTL Example and ready to compile and run
- Add simple RAM RTL and simple sanity test
- Create a seperate template file for configuring generated code
- Code CLI for tbengy
- Add support for simple SV TB
- Add generation of synthesis script for Digilent/Xilinx FPGA boards for validation
- Add support to select Digilent Xilinx FPGA boards to auto-synthesize, elaboration and implementation with programming bitstream on board
- Add support to select f4pga tool (https://f4pga.readthedocs.io/en/latest/getting-started.html) to auto-synthesize, elaboration and implementation with programming bitstream on board based on Lattice iCE40, ECP5 and Xilinx-7 Series FPGA as an alternate option
-
Add support for Modelsim compilation instruction in Makefile -
Add support for Vivado wdb wave dump to Modelsim WLF dump conversion for debugging waves generated by Vivado in Modelsim (May or may not happen)